WO2021111494A1 - Synchronization method and information equipment - Google Patents

Abstract

This synchronization method includes: a first step for transmitting, to a communication device that time-synchronizes with a base station device connected to a mobile body communication network, an inquiry command, a plurality of times, for requesting time information represented by a first unit lower in accuracy than time synchronization realized by the communication device; a second step for determining a timing of updating the time information acquired in response to the inquiry command; a third step for determining the next timing of transmitting the inquiry command on the basis of the timing of updating the time information; and a fourth step for acquiring time information with accuracy higher than that in the first unit on the basis of time information acquired in response to the inquiry command transmitted in the third step.

Description

Synchronization method and information equipment

The present invention relates to a time synchronization technique.

In recent years, with the spread of sensor networks and the like, the demand for highly accurate time synchronization is increasing. As one of the solutions to such demands, a method using GPS (Global Positioning System) has been proposed. However, such a method cannot be adopted in a place where GPS radio waves do not reach. For example, in places such as indoors, under bridges, underground, and tunnels, GPS radio waves do not reach, so time synchronization using GPS cannot be realized. On the other hand, there is a demand for highly accurate time synchronization even in places where GPS radio waves do not reach.

NTP (Network Time Protocol) may be used in places where GPS radio waves do not reach. NTP is a time synchronization system that utilizes Ethernet (registered trademark) transmission. However, the synchronization accuracy of NTP is about millisecond, which is low. In NTP, the Internet, which is a best effort network, is used. Therefore, there is no absolute guarantee, and the accuracy may be very poor.

Similarly, there is PTP (Precision Time Protocol) as a protocol for performing highly accurate time synchronization using Ethernet (registered trademark) transmission. PTP guarantees accuracy of microseconds or less. However, in PTP, high-precision time synchronization is realized by adding a high-precision hardware time stamp and relaying by a corresponding network device that accurately detects and corrects the propagation delay of the network. Therefore, in PTP, special functions are required for all network devices between ends.

Further, in a mobile communication network such as LTE, highly accurate time synchronization is realized between a terminal device and a base station. Radio waves used in mobile communication networks often reach areas beyond the reach of radio waves transmitted from GPS satellites. Therefore, a communication device (modem or the like) connected to the mobile communication network can realize highly accurate time synchronization even in a place where GPS radio waves do not reach. Further, a command for outputting synchronization information may be defined in a communication device connected to such a mobile communication network (see, for example, Patent Document 1).

However, the synchronization information provided in Non-Patent Document 1 is the synchronization information in seconds, and the synchronization information with an accuracy of less than seconds is not provided. Therefore, even if there is a modem connected to the mobile communication network, other information devices cannot realize highly accurate time synchronization. As described above, a technique for economically highly accurate time synchronization is not provided in a place where GPS radio waves do not reach.

In view of the above circumstances, an object of the present invention is to provide a technique capable of realizing more economical and more accurate time synchronization even in a place where GPS radio waves do not reach.

One aspect of the present invention is a unit having a accuracy lower than the time synchronization accuracy realized by the communication device with respect to the communication device that synchronizes the time with the base station device connected to the mobile communication network. The first step of transmitting an inquiry command requesting time information expressed in the first unit a plurality of times, the second step of determining the timing at which the time information obtained as a response of the inquiry command is updated, and the above. Based on the timing at which the time information is updated, the third step of determining when to transmit the inquiry command next, and the time information obtained as a response of the inquiry command transmitted in the third step, are used. This is a synchronization method including a fourth step of acquiring time information with higher accuracy than the first unit.

One aspect of the present invention is a unit having a accuracy lower than the time synchronization accuracy realized by the communication device with respect to the communication device that synchronizes the time with the base station device connected to the mobile communication network. The inquiry command requesting the time information expressed in the first unit is transmitted a plurality of times, the timing at which the time information obtained as a response of the inquiry command is updated is determined, and the timing at which the time information is updated is determined. Based on this, the control unit that determines the timing to transmit the inquiry command next and acquires the time information with higher accuracy than the first unit based on the time information obtained as the response of the transmitted inquiry command. It is an information device to be equipped.

According to the present invention, it is possible to realize more economical and more accurate time synchronization even in a place where GPS radio waves do not reach.

It is a schematic block diagram which shows the outline of the functional structure of the synchronization system 100 of this invention. It is a figure which shows the specific example of the hardware composition of the information device 10. It is a figure which shows the structural example of the modification of the synchronization system 100.

An embodiment of the receiving device of the present invention will be described in detail with reference to the drawings.
[Summary]
FIG. 1 is a schematic block diagram showing an outline of a functional configuration of the synchronization system 100 of the present invention. First, the outline of the synchronization system 100 will be described. The synchronization system 100 of the present invention includes an information device 10 and a base station device 20. The communication device 11 of the information device 10 synchronizes the time by communicating with the base station device 20. Time synchronization by the communication device 11 is realized with high accuracy based on the protocol of the mobile communication network. The control unit 12 acquires a plurality of synchronization information by transmitting a synchronization information inquiry command to the communication device 11 a plurality of times at a cycle shorter than one second. The control unit 12 synchronizes the time based on the timing when the value indicating "second" included in the synchronization information changes. Such processing makes it possible to perform time synchronization with a period shorter than 1 second (higher accuracy). Hereinafter, the details of the synchronization system 100 of the present invention will be described.

[Details]
The information device 10 is a device that wirelessly communicates with the base station device 20. The base station device 20 is connected to the mobile communication network 30 and communicates with the information device 10 using a predetermined wireless communication protocol. Specific examples of predetermined wireless communication protocols include LTE and LTE-Advanced (TD-LTE).

In LTE-Advanced, the required synchronization accuracy between the base station devices 20 is G.8271 of ITU-T (International Telecommunication Union-Telecommunication Standardization Sector), and the time error from Coordinated Universal Time (UTC) is 1.5. It is specified to be microseconds or less. Further, in CoMP (Coordinated Multipoint Transmission), time / phase synchronization accuracy of several hundred nanoseconds is required. In CoMP, it is defined that information such as communication quality with a terminal (for example, information device 10) is exchanged between adjacent base station devices 20 to adjust transmission power and resource allocation of the base station device 20.

In LTE, the base station device 20 notifies two synchronization signals, a primary synchronization signal (PSS: Primary Synchronization Signal) and a secondary synchronization signal (SSS: Secondary Synchronization Signal), at a cycle of several milliseconds. The communication device of the terminal (for example, the information device 10) synchronizes the time with the base station device 20 based on these two synchronization signals.

As described above, highly accurate time synchronization is realized between the base station device 20 constituting the mobile communication network and the information device 10 based on the wireless communication protocol of mobile communication.

The information device 10 is a device that performs information processing. The information device 10 may be, for example, a sensor, a logger of a sensor network, or a user terminal. Specific examples of user terminals include smartphones, mobile phones, tablets, personal computers, wearable terminals, game devices, and home appliances. The information device 10 includes a communication device 11 and a control unit 12.

The communication device 11 is communication hardware such as a communication modem. The communication device 11 communicates with the base station device 20 using a predetermined mobile communication wireless communication protocol. As described above, the communication device 11 realizes highly accurate time synchronization with the base station device 20.

The control unit 12 is configured by using a processor such as a CPU and a memory. The control unit 12 operates by the processor reading and executing the program stored in the storage device. The program may be recorded on a computer-readable recording medium. The computer-readable recording medium is, for example, a flexible disk, a magneto-optical disk, a portable medium such as a ROM or a CD-ROM, or a non-temporary storage medium such as a storage device such as a hard disk built in a computer system. The program may be transmitted over a telecommunication line. Part or all of the operation of the control unit 12 may be realized by using hardware including an electronic circuit using, for example, LSI, ASIC, PLD, FPGA, or the like.

The control unit 12 transmits a synchronization information inquiry command to the communication device 11 a plurality of times in a cycle shorter than 1 second. The inquiry command is, for example, a command for inquiring synchronization information according to the time synchronization performed by the communication device 11 with the base station device 20. As a response to the inquiry command, time information is sent from the communication device 11 to the control unit 12 in a unit of accuracy lower than the accuracy of time synchronization actually realized by the communication device 11 (hereinafter referred to as "first unit"). It is output. For example, time information with an accuracy of seconds may be output.

The control unit 12 refers to the synchronization information obtained in response to each inquiry command. The control unit 12 performs time synchronization based on the timing at which the value indicating the first unit (for example, “second”) included in the synchronization information changes (specifically, increments). By such processing, it is possible to perform time synchronization in a unit having a higher accuracy than the first unit (hereinafter referred to as "second unit"). A specific example of such processing will be described in detail. In the following description, "second" is used as a specific example of the first unit in order to simplify the description.

The control unit 12 transmits a synchronization information inquiry command to the communication device 11 at intervals of time T. That is, the inquiry command is transmitted in the cycle T. The period T is preferably a time shorter than the minimum value (1 second) of seconds, which is the first unit. By shortening the period T, the time required to acquire more accurate synchronization information can be shortened. However, if a new inquiry command is transmitted before receiving the response signal to the inquiry command, the communication device 11 may overwrite the inquiry command. If the query command is overwritten, it may not be possible to receive an accurate response signal. Therefore, the period T may be set according to such a trade-off relationship.

The control unit 12 repeats the transmission of the inquiry command until the synchronization information related to the response signal obtained from the communication device 11 is updated. Specifically, updating the synchronization information means that in this case, the value indicating the first unit is incremented.

When the synchronization information related to the response signal from the communication device 11 is updated, the control unit 12 then bases the transmission time "P1" of the inquiry command immediately before corresponding to the response signal, the period T, and so on. Controls when the query command is sent. For example, the control unit 12 defines a value obtained by subtracting a time T1 (that is, T> T1), which is a time shorter than the period T, from 1 second, which is the first unit, as a difference time. Then, the control unit 12 may determine the timing at which the difference time has elapsed from the transmission time “P1” of the immediately preceding inquiry command as the timing “P2” for transmitting the next inquiry command. T1 may be obtained in any way. For example, T1 may be obtained by dividing T by m, which is an integer greater than or equal to 1.

The control unit 12 determines the timing "P3" for transmitting the inquiry command next, based on the synchronization information related to the response signal received in response to the inquiry command transmitted at the timing "P2". Specifically, it is as follows. The control unit 12 defines a value T2 that is even smaller than T1. For example, the value obtained by dividing T by the value of m to the nth power (n is an integer of 1 or more) may be defined as T2. The value of "n" in this case may be "2". That is, the timing when the updated synchronization information is obtained by repeatedly transmitting the inquiry command in the cycle T is defined as n = 1 as the transmission time “Pn”, and the value of n is changed each time the inquiry command is subsequently transmitted. It may be incremented. The control unit 12 determines the timing “P3” using the value of T2.

When the synchronization information related to the response signal of the timing "P2" is updated, the control unit 12 defines a value obtained by subtracting the time T2 from the first unit of 1 second as the difference time. Then, the control unit 12 may determine the timing at which the difference time has elapsed from the transmission time “P2” of the immediately preceding inquiry command as the timing “P3” for transmitting the next inquiry command.

When the synchronization information related to the response signal of the timing "P2" has not been updated, the control unit 12 defines a value obtained by adding the time T2 to the first unit of 1 second as the difference time. Then, the control unit 12 may determine the timing at which the difference time has elapsed from the transmission time “P2” of the immediately preceding inquiry command as the timing “P3” for transmitting the next inquiry command.

The value to be added or subtracted from the time T1 and the time T2 may be 1 second, which is the minimum value of the first unit, or the first unit, which is not the minimum value, such as 2 seconds and 3 seconds. It may be the value of. The control unit 12 repeatedly executes the above process (a process of determining the timing "P3" based on the timing "P2" and transmitting an inquiry command) a predetermined number of times while incrementing the value of n. To do. The control unit 12 acquires time information based on the synchronization information related to the response signal finally obtained by the repeated execution.

Specifically, it is as follows. The transmission time of the immediately preceding inquiry command is defined as "Pn". The control unit 12 defines a value Tn that is even smaller than T (n-1) used when determining the transmission time of the immediately preceding inquiry command. For example, the value obtained by dividing T by the value of m to the nth power may be defined as Tn. The control unit 12 determines the time information using the value of Tn.

When the synchronization information related to the response signal of the timing "Pn" is updated, the control unit 12 defines a value obtained by subtracting the time Tn from the first unit of 1 second as the difference time. Then, the control unit 12 determines that the timing at which the difference time has elapsed from the transmission time “Pn” of the immediately preceding inquiry command is the update timing of the first unit (for example, seconds).

When the synchronization information related to the response signal of the timing "P2" has not been updated, the control unit 12 defines a value obtained by adding the time Tn to 1 second, which is the first unit, as the difference time. Then, the control unit 12 determines that the timing at which the difference time has elapsed from the transmission time “Pn” of the immediately preceding inquiry command is the update timing of the first unit (for example, seconds).

By performing such processing, it is possible to perform time synchronization with a shorter cycle (higher accuracy) than the first unit.

FIG. 2 is a diagram showing a specific example of the hardware configuration of the information device 10. The communication device 11 may be configured by using, for example, a communication modem compatible with LTE or the like. The control unit 12 may be configured by using a processor 12a such as a CPU. Between the communication modem 11a and the processor 12a, control by an inquiry command and its response are performed via, for example, a UART (Universal Asynchronous Receiver / Transmitter) interface 101. Further, flow control and the like are performed via the I / O interface 102. Then, an interrupt such as wireless packet reception is performed via the INT interface 103. Power is supplied to the communication modem 11a and the processor 12a from the power supply 13. A SIM (Subscriber Identity Module) card 14 is connected to the communication modem 11a. The communication modem 11a uses the information recorded in the SIM card 14 to perform wireless communication with the base station apparatus 20.

FIG. 3 is a diagram showing a configuration example of a modified example of the synchronization system 100 (synchronization system 100a). In FIG. 1, one information device 10 is provided with a communication device 11 and a control unit 12. That is, it corresponds to a communication device 11 corresponding to a communication device that realizes highly accurate time synchronization with the base station device 20, and a device that acquires time information by transmitting an inquiry command to the communication device 11. The control unit 12 is provided in the same device (information device 10). On the other hand, in the example shown in FIG. 3, an inquiry command is issued to the first communication device 41, which corresponds to a communication device that realizes highly accurate time synchronization with the base station device 20, and the first communication device 41. The control unit 51, which corresponds to a device that acquires time information by transmission, is provided in different devices (communication device 40 and information device 50). The communication device 40 and the information device 50 communicate with each other via the second communication device 42 and the communication unit 52, respectively. Through this communication, the control unit 51 transmits an inquiry command to the first communication device 41, and the control unit 51 acquires synchronization information from the first communication device 41. The communication between the second communication device 42 and the communication unit 52 may be wireless communication or wired communication. The same effect as that of the synchronization system 100 shown in FIG. 1 can be obtained by the configuration of the modified example configured in this way.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes designs and the like within a range that does not deviate from the gist of the present invention.

The present invention is applicable to a system using time synchronization.

100, 100a ... Synchronous system, 10 ... Information equipment, 11 ... Communication device, 12 ... Control unit, 13 ... Power supply, 14 ... SIM card, 20 ... Base station device, 30 ... Mobile communication network, 101 ... UART interface, 102 ... I / O interface, 103 ... INT interface, 40 ... Communication equipment, 41 ... First communication device, 42 ... Second communication device, 50 ... Information equipment, 51 ... Control unit, 52 ... Communication unit

Claims (3)

1. For a communication device that synchronizes time with a base station device connected to a mobile communication network, it is represented by the first unit, which is a unit of accuracy lower than the accuracy of time synchronization realized by the communication device. The first step of sending a query command requesting time information multiple times,
   The second step of determining the timing at which the time information obtained as a response of the inquiry command is updated, and
   Based on the timing at which the time information is updated, the third step of determining when to send the inquiry command next, and
   The fourth step of acquiring the time information with higher accuracy than the first unit based on the time information obtained as the response of the inquiry command transmitted in the third step, and the fourth step.
   A synchronization method that includes.
2. Including a plurality of the third steps,
   In the fourth step, the time information is acquired with higher accuracy than the first unit based on the time information obtained as the response of the inquiry command in the third step executed last.
   The synchronization method according to claim 1.
3. For a communication device that synchronizes time with a base station device connected to a mobile communication network, it is represented by the first unit, which is a unit of accuracy lower than the accuracy of time synchronization realized by the communication device. The inquiry command requesting the time information is transmitted a plurality of times, the timing at which the time information obtained as a response of the inquiry command is updated is determined, and the inquiry is then made based on the timing at which the time information is updated. A control unit that determines the timing of sending a command and acquires the time information with higher accuracy than the first unit based on the time information obtained as a response of the sent inquiry command.
   Information equipment equipped with.

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